Optimization of Fermentation Conditions to Enhance Cytotoxic Metabolites Production by Strain RP137 from the Persian Gulf

Overview

Journal Avicenna J Med Biotechnol

Specialty Biomedical Engineering

Date 2020 May 21

PMID 32431796

Citations 3

Authors

Roya Pournejati

Hamid Reza Karbalaei-Heidari

Affiliations

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Abstract

Background: Isolation, introduction and producing bioactive compounds from bacteria, especially marine bacteria, is an attractive research area. One of the main challenges of using these metabolites as drug and their industrialization is the optimization of production conditions.

Methods: In the present study, the response surface methodology was applied to optimize the production of a cytotoxic extract (C-137-R) by () strain RP137. Initially, among the three carbon and three nitrogen sources, rice starch and potassium nitrate were selected as the best, with cell toxicity equal to IC50=54.4 and 45.1 in human lung and liver cancer cell lines, respectively (A549 and HepG2). In the next step, fractional factorial design was performed to survey effect of seven physical and chemical factors on the amount of production, and the most important factors including carbon and nitrogen sources with the positive effect and the sea salt with negative effect were determined. Finally, using the central composite design with 20 experiments, the best concentrations of rice starch and potassium nitrate (1.5%) and sea salt (1%) were obtained.

Results: The average amount of dried extract produced in the optimum conditions was 131.1 and the best response was 71.45%, which is more than 28-fold better than the pre-optimized conditions.

Conclusion: In general, it can be suggested that the use of modern statistical methods to optimize environmental conditions affecting the growth and metabolism of bacteria can be a highly valuable tool in industrializing the production of bioactive compounds.

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